Fixative-Dependent Increase in Immunogold Labeling following Antigen Retrieval on Acrylic and Epoxy Sections

We examined the increase in immunogold labeling of variably fixed, resin embedded tissue sections following antigen retrieval by heating in citrate solution. Fibrin clots and porcine renal tissue were fixed in glutaraldehyde, paraformaldehyde or ethanol, and specimens were embedded in LR-White or epoxy resin. Immunogold labeling was performed on ultra-thin sections with anti-fibrinogen for the fibrin clots and anti-IgG for the porcine renal tissue. Immunogold labeling increased greatly after heating epoxy sections regardless of the fixative used. The ratio labeling_retrieved/labeling_nonretrieved (L_r/L_n) was 2.8 or higher, and the largest increases were obtained for anti-IgG. Heating induced a large increase of immunolabeling for LR-White sections only when the specimens had been fixed in paraformaldehyde (L_r/L_n = 2.2 for anti-IgG and 1.4 for antifibrinogen). LR-White sections showed decreased, insignificant or weakly increased immunolabeling of ethanol or glutaraldehyde fixed tissues following antigen retrieval. Disruption of aldehyde cross-links is not the only mechanism for antigen retrieval when epoxy sections are heated in citrate solution since large increases in immunolabeling were obtained on ethanol fixed tissue. The large heat-induced increases in immunolabeling on epoxy sections are probably caused by the disruption of chemical bonds between the epoxy resin and side groups of proteins.     

Fixative-Dependent Increase in Immunogold Labeling following Antigen Retrieval on Acrylic and Epoxy Sections

We examined the increase in immunogold labeling of variably fixed, resin embedded tissue sections following antigen retrieval by heating in citrate solution. Fibrin clots and porcine renal tissue were fixed in glutaraldehyde, paraformaldehyde or ethanol, and specimens were embedded in LR-White or epoxy resin. Immunogold labeling was performed on ultra-thin sections with anti-fibrinogen for the fibrin clots and anti-IgG for the porcine renal tissue. Immunogold labeling increased greatly after heating epoxy sections regardless of the fixative used. The ratio labeling_retrieved/labeling_nonretrieved (L_r/L_n) was 2.8 or higher, and the largest increases were obtained for anti-IgG. Heating induced a large increase of immunolabeling for LR-White sections only when the specimens had been fixed in paraformaldehyde (L_r/L_n = 2.2 for anti-IgG and 1.4 for antifibrinogen). LR-White sections showed decreased, insignificant or weakly increased immunolabeling of ethanol or glutaraldehyde fixed tissues following antigen retrieval. Disruption of aldehyde cross-links is not the only mechanism for antigen retrieval when epoxy sections are heated in citrate solution since large increases in immunolabeling were obtained on ethanol fixed tissue. The large heat-induced increases in immunolabeling on epoxy sections are probably caused by the disruption of chemical bonds between the epoxy resin and side groups of proteins.     

Antigen retrieval in cells and tissues: enhancement with sodium dodecyl sulfate

Immunocytochemistry provides important information on the localization of antigens in cells and tissues. However, the procedures used to prepare cells and tissues for immunocytochemical labeling may have deleterious effects on the results achieved. That is, the antigen of interest may be difficult or impossible to detect following labeling. These sorts of observations have led to the concept of antigen masking in which the antigen (or specific epitope) is hidden from antibodies specific for that antigen (or epitope). Various procedures to circumvent this problem have been developed. These different procedures generally fit under the term "antigen retrieval" (or epitope retrieval). The practice of antigen retrieval is widely employed with paraffin-embedded material. Antigen retrieval is less often applied to cells and tissues that are not embedded in paraffin. However, in the latter preparations there are situations in which the observed immunolabeling achieved falls short of expectations. This poor level of immunolabeling may, in some situations, be improved upon with antigen retrieval procedures. In this review, we describe experimental situations in which immunolabeling fell short of expectations. We also describe a procedure that has been useful in enhancing immunolabeling efficiency in these cases. The major feature of this procedure is the incorporation of a permeabilization/denaturation step using sodium dodecyl sulfate. This postfixation and prelabeling step dramatically improves immunolabeling for a number of antigens in both cells and cryosections of tissue.     

Calcitonin and chromogranin A localization in medullary carcinoma of the thyroid by immunoelectron microscopy

We used a post-embedding immunoelectron microscopy method, using protein A-gold, to detect calcitonin and chromogranin A immunoreactivity in three cases of human medullary thyroid carcinoma. Because the epoxy-embedded tissue had been fixed (glutaraldehyde or formaldehyde) and osmicated before embedment, the proteins were identified in optimally preserved tissue. Uranyl and lead staining was used after immunolabeling, so that the tissue was also optimally contrasted. The morphological advantage provided by osmication was tested by labeling rat thyroid gland C-cells for calcitonin. The protein A-gold technique allowed localization of both antigens to the contents of membrane-bound secretory granules in the tumor cells. In one case, labeling density for each antigen was measured over several intercellular compartments and the interstitium. Calcitonin, but not chromogranin A, reactivity was also identified in intracellular amyloid fibrils in two cases, showing that the constant region of calcitonin is preserved in amyloid deposits related to the tumor cells.     

Collagenase predigestion on paraffin sections enhances collagen immunohistochemical detection without distorting tissue morphology

Reliable immunohistochemical detection of collagen in formalin fixed, paraffin embedded tissues requires protease digestion. While these pan-proteases (pepsin, trypsin, protease K, etc.) enhance collagen detection, they also digest many other tissue proteins and produce poor cellular morphology and unrecognizable cellular structures. Balancing the conditions (protease type, concentration, incubation time and temperature) to digest some, but not all, proteins in a tissue section while optimizing collagen detection requires one to compromise improved collagen immunolabeling with adequate cellular morphology. Furthermore, optimal conditions for digesting tissue proteins to enhance collagen detection vary among tissue types and their fixation. Although brain is not typically subject to these deleterious consequences, structures such as epithelium, spermatids, stroma etc. and other tissues with complicated histology are profoundly affected. To resolve this technical dilemma, we discovered a novel use for collagenase to enhance collagen immunodetection without affecting the noncollagen proteins, thereby preserving tissue morphology. Collagenase, which is typically used in vitro for disassociation of cells, has never been used reliably on formalin fixed, paraffin embedded tissue sections. This new use of collagenase for immunohistochemistry promotes increased collagen immunolabeling, is easy to use, is versatile, and allows preservation of tissue structure that provides maximal and accurate histological information.     

Collagenase predigestion on paraffin sections enhances collagen immunohistochemical detection without distorting tissue morphology

Reliable immunohistochemical detection of collagen in formalin fixed, paraffin embedded tissues requires protease digestion. While these pan-proteases (pepsin, trypsin, protease K, etc.) enhance collagen detection, they also digest many other tissue proteins and produce poor cellular morphology and unrecognizable cellular structures. Balancing the conditions (protease type, concentration, incubation time and temperature) to digest some, but not all, proteins in a tissue section while optimizing collagen detection requires one to compromise improved collagen immunolabeling with adequate cellular morphology. Furthermore, optimal conditions for digesting tissue proteins to enhance collagen detection vary among tissue types and their fixation. Although brain is not typically subject to these deleterious consequences, structures such as epithelium, spermatids, stroma etc. and other tissues with complicated histology are profoundly affected. To resolve this technical dilemma, we discovered a novel use for collagenase to enhance collagen immunodetection without affecting the noncollagen proteins, thereby preserving tissue morphology. Collagenase, which is typically used in vitro for disassociation of cells, has never been used reliably on formalin fixed, paraffin embedded tissue sections. This new use of collagenase for immunohistochemistry promotes increased collagen immunolabeling, is easy to use, is versatile, and allows preservation of tissue structure that provides maximal and accurate histological information.     

Intravital Imaging of the Mouse Popliteal Lymph Node

Lymph nodes (LNs) are secondary lymphoid organs, which are strategically located throughout the body to allow for trapping and presentation of foreign antigens from peripheral tissues to prime the adaptive immune response. Juxtaposed between innate and adaptive immune responses, the LN is an ideal site to study immune cell interactions^1,2. Lymphocytes (T cells, B cells and NK cells), dendritic cells (DCs), and macrophages comprise the bulk of bone marrow-derived cellular elements of the LN. These cells are strategically positioned in the LN to allow efficient surveillance of self antigens and potential foreign antigens^3-5. The process by which lymphocytes successfully encounter cognate antigens is a subject of intense investigation in recent years, and involves an integration of molecular contacts including antigen receptors, adhesion molecules, chemokines, and stromal structures such as the fibro-reticular network^2,6-12. Prior to the development of high-resolution real-time fluorescent in vivo imaging, investigators relied on static imaging, which only offers answers regarding morphology, position, and architecture. While these questions are fundamental in our understanding of immune cell behavior, the limitations intrinsic with this technique does not permit analysis to decipher lymphocyte trafficking and environmental clues that affect dynamic cell behavior. Recently, the development of intravital two-photon laser scanning microscopy (2P-LSM) has allowed investigators to view the dynamic movements and interactions of individual cells within live LNs in situ^12-16. In particular, we and others have applied this technique to image cellular behavior and interactions within the popliteal LN, where its compact, dense nature offers the advantage of multiplex data acquisition over a large tissue area with diverse tissue sub-structures^11,17-18. It is important to note that this technique offers added benefits over explanted tissue imaging techniques, which require disruption of blood, lymph flow, and ultimately the cellular dynamics of the system. Additionally, explanted tissues have a very limited window of time in which the tissue remains viable for imaging after explant. With proper hydration and monitoring of the animal''s environmental conditions, the imaging time can be significantly extended with this intravital technique. Here, we present a detailed method of preparing mouse popliteal LN for the purpose of performing intravital imaging.     

Correlative light and electron microscopy (CLEM) as a tool to visualize microinjected molecules and their eukaryotic sub-cellular targets

The eukaryotic cell relies on complex, highly regulated, and functionally distinct membrane bound compartments that preserve a biochemical polarity necessary for proper cellular function. Understanding how the enzymes, proteins, and cytoskeletal components govern and maintain this biochemical segregation is therefore of paramount importance. The use of fluorescently tagged molecules to localize to and/or perturb subcellular compartments has yielded a wealth of knowledge and advanced our understanding of cellular regulation. Imaging techniques such as fluorescent and confocal microscopy make ascertaining the position of a fluorescently tagged small molecule relatively straightforward, however the resolution of very small structures is limited. On the other hand, electron microscopy has revealed details of subcellular morphology at very high resolution, but its static nature makes it difficult to measure highly dynamic processes with precision. Thus, the combination of light microscopy with electron microscopy of the same sample, termed Correlative Light and Electron Microscopy (CLEM), affords the dual advantages of ultrafast fluorescent imaging with the high-resolution of electron microscopy. This powerful technique has been implemented to study many aspects of cell biology. Since its inception, this procedure has increased our ability to distinguish subcellular architectures and morphologies at high resolution. Here, we present a streamlined method for performing rapid microinjection followed by CLEM (Fig. 1). The microinjection CLEM procedure can be used to introduce specific quantities of small molecules and/or proteins directly into the eukaryotic cell cytoplasm and study the effects from millimeter to multi-nanometer resolution (Fig. 2). The technique is based on microinjecting cells grown on laser etched glass gridded coverslips affixed to the bottom of live cell dishes and imaging with both confocal fluorescent and electron microscopy. Localization of the cell(s) of interest is facilitated by the grid pattern, which is easily transferred, along with the cells of interest, to the Epon resin used for immobilization of samples and sectioning prior to electron microscopy analysis (Fig. 3). Overlay of fluorescent and EM images allows the user to determine the subcellular localization as well as any morphological and/or ultrastructural changes induced by the microinjected molecule of interest (Fig. 4). This technique is amenable to time points ranging from ≤5 s up to several hours, depending on the nature of the microinjected sample.     

FluoroNanogold: an important probe for correlative microscopy

Correlative microscopy is a powerful imaging approach that refers to observing the same exact structures within a specimen by two or more imaging modalities. In biological samples, this typically means examining the same sub-cellular feature with different imaging methods. Correlative microscopy is not restricted to the domains of fluorescence microscopy and electron microscopy; however, currently, most correlative microscopy studies combine these two methods, and in this review, we will focus on the use of fluorescence and electron microscopy. Successful correlative fluorescence and electron microscopy requires probes, or reporter systems, from which useful information can be obtained with each of the imaging modalities employed. The bi-functional immunolabeling reagent, FluoroNanogold, is one such probe that provides robust signals in both fluorescence and electron microscopy. It consists of a gold cluster compound that is visualized by electron microscopy and a covalently attached fluorophore that is visualized by fluorescence microscopy. FluoroNanogold has been an extremely useful labeling reagent in correlative microscopy studies. In this report, we present an overview of research using this unique probe.     

Phenotyping of protein-prion (PrPsc)-accumulating cells in lymphoid and neural tissues of naturally scrapie-affected sheep by double-labeling immunohistochemistry.

Transmissible spongiform encephalopathies are fatal neurodegenerative diseases characterized by amyloid deposition of protein-prion (PrPsc), the pathogenic isoform of the host cellular protein PrPc, in the immune and central nervous systems. In the absence of definitive data on the nature of the infectious agent, PrPsc immunohistochemistry (IHC) constitutes one of the main methodologies for pathogenesis studies of these diseases. In situ PrPsc immunolabeling requires formalin fixation and paraffin embedding of tissues, followed by post-embedding antigen retrieval steps such as formic acid and hydrated autoclaving treatments. These procedures result in poor cellular antigen preservation, precluding the phenotyping of cells involved in scrapie pathogenesis. Until now, PrPsc-positive cell phenotyping relied mainly on morphological criteria. To identify these cells under the PrPsc IHC conditions, a new, rapid, and highly sensitive PrPsc double-labeling technique was developed, using a panel of screened antibodies that allow specific labeling of most of the cell subsets and structures using paraffin-embedded lymphoid and neural tissues from sheep, leading to an accurate identification of ovine PrPsc-accumulating cells. This technique constitutes a useful tool for IHC investigation of scrapie pathogenesis and may be applicable to the study of other ovine infectious diseases.     

Long-term Intravital Immunofluorescence Imaging of Tissue Matrix Components with Epifluorescence and Two-photon Microscopy

Besides being a physical scaffold to maintain tissue morphology, the extracellular matrix (ECM) is actively involved in regulating cell and tissue function during development and organ homeostasis. It does so by acting via biochemical, biomechanical, and biophysical signaling pathways, such as through the release of bioactive ECM protein fragments, regulating tissue tension, and providing pathways for cell migration. The extracellular matrix of the tumor microenvironment undergoes substantial remodeling, characterized by the degradation, deposition and organization of fibrillar and non-fibrillar matrix proteins. Stromal stiffening of the tumor microenvironment can promote tumor growth and invasion, and cause remodeling of blood and lymphatic vessels. Live imaging of matrix proteins, however, to this point is limited to fibrillar collagens that can be detected by second harmonic generation using multi-photon microscopy, leaving the majority of matrix components largely invisible. Here we describe procedures for tumor inoculation in the thin dorsal ear skin, immunolabeling of extracellular matrix proteins and intravital imaging of the exposed tissue in live mice using epifluorescence and two-photon microscopy. Our intravital imaging method allows for the direct detection of both fibrillar and non-fibrillar matrix proteins in the context of a growing dermal tumor. We show examples of vessel remodeling caused by local matrix contraction. We also found that fibrillar matrix of the tumor detected with the second harmonic generation is spatially distinct from newly deposited matrix components such as tenascin C. We also showed long-term (12 hours) imaging of T-cell interaction with tumor cells and tumor cells migration along the collagen IV of basement membrane. Taken together, this method uniquely allows for the simultaneous detection of tumor cells, their physical microenvironment and the endogenous tissue immune response over time, which may provide important insights into the mechanisms underlying tumor progression and ultimate success or resistance to therapy.     

Correlation of histology and linear and nonlinear microscopy of the living human cornea

The morphology and the function of cellular and non‐cellular structures in the living human cornea can be determined with modern correlative linear and nonlinear optical microscopic techniques and histology. Correlative microscopy is based on the use of different optical techniques to study the same specimen, ideally at the same location within the specimen, in order to increase the functional and/or morphological understanding of the specimen. A case study to assess the effect of overnight lid‐closure on in vivo human corneal morphology is presented to illustrate correlative linear microscopy and optical low‐coherence reflectometry. Nonlinear multiphoton excitation microscopy provides functional information on cellular metabolism based on the intrinsic fluorescence from the reduced pyridine nucleotides and the oxidized flavoproteins. Second‐harmonic generation microscopy, a scattering process that does not deposit net energy into the tissue, provides structural information on corneal collagen organization. Molecular third‐harmonic generation microscopy generates a signal in all materials and it an emerging technique. Coherent anti‐Stokes Raman scattering microscopy provides chemical imaging for biology and medicine. The comparison and limitations of these microscopic modalities, linear and nonlinear microscopy applied to the cornea, and a review of some key findings is analyzed. A correlative integration and correlation of linear and nonlinear microscopies to study corneal function and structure is proposed to validate the clinical interpretation of microscopic images of the cornea. (© 2009 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

IMMUNOGOLD LABELLING OF FIBROBLAST FOCAL ADHESION SITES VISUALISED IN FIXED MATERIAL USING SCANNING ELECTRON MICROSCOPY, AND LIVING, USING INTERNAL REFLECTION MICROSCOPY

A new immunogold labelling method for the visualisation of vinculin, an integral protein in focal adhesions of cells, is reported. Quantification of vinculin is indicative of substrate cytocompatibility (cytocompatibility is one aspect of biocompatibility; it is the cellular response to a biomaterial). For efficient labelling, most of the cell body above the cell-substrate interface was removed with detergent. The antigen blocking procedure, size of label (5 nm) and duration of silver-enhancement (6 min), for visualisation of the labelled sites on the whole cell by scanning electron microscopy (SEM), were determined. Imaging living cells with interference reflection light microscopy, followed by backscattered electron (BSE) imaging of the same fixed and immunolabelled cells confirmed the results. Collecting low voltage BSE images of embedded cells after the substrate had been removed provided 'sectional' views through the cell. This enabled visualisation of vinculin exclusively within the cell-substrate contact zone; the focal adhesions. The method could be of general use in the imaging of protein distribution at biological tissue/substrate interfaces.     

Tissue and Cellular Localization of Proteinase Inhibitors I and II in the Fruit of the Wild Tomato, Lycopersicon peruvianum (L.) Mill

The cellular and subcellular localization of proteinase inhibitor I and inhibitor II proteins in the fruit of the wild tomato species Lycopersicon peruvianum (L.) Mill., LA 107 was determined by immunoanalysis of tissue blots and protein-A gold immunocytochemistry. Tissue blot analysis showed that the proteinase inhibitor I proteins were located throughout the fruit tissue, with the exception of the seeds. Light microscopy, using immunocytochemical labeling, indicated that all the parenchyma cells of the pericarp contained inhibitor I and II proteins in dense vacuolar protein aggregates that were not membrane bound. The size, number, and morphology of the aggregates within individual cells varied greatly. The funiculus, ovule, and early embryonic tissues were devoid of inhibitor I and II. Immunocytochemical analysis using transmission electron microscopy confirmed that the proteinase inhibitor I proteins were principally located and stored in protein aggregates within the vacuole of the fruit parenchyma cells. Some cytoplasmic protein-A gold immunolabeling of inhibitor I proteins was evident, which may be related to the synthesis and intermediate transport steps preceding storage of the inhibitor I proteins in the vacuoles.     

A technique for retrieving antigens in formalin-fixed, routinely acid-decalcified, celloidin-embedded human temporal bone sections for immunohistochemistry.

The application of immunohistochemistry to routinely decalcified, celloidin-embedded human temporal bone sections has been hampered because of antigen loss during processing of the specimens. To our knowledge, there has been no published report to date describing immunohistochemical staining of such tissues suitable for examination by light microscopy. Here we report a novel antigen retrieval technique which can be successfully used to stain a variety of antigens in routinely formalin-fixed, trichloroacetic acid-decalcified, celloidin-embedded human temporal bone sections. The new procedure reported here for decalcified human temporal bone tissues simply requires immersing slides for 30 min at room temperature in an antigen retrieval solution. A total of 60 decalcified, celloidin-embedded human temporal bone tissues were tested with monoclonal antibodies (MAb) to 15 different antigens. Of these, 12 MAb showed definite positive staining, while three were negative. This technique may prove very useful in studying the expression of various antigens by immunohistochemistry in formalin-fixed, acid-decalcified, celloidin-embedded tissues.     

In vivo imaging of green fluorescent protein-expressing cells in transgenic animals using fibred confocal fluorescence microscopy

Animal imaging requires the use of reliable long-term fluorescence methods and technology. The application of confocal imaging to in vivo monitoring of transgene expression within internal organs and tissues has been limited by the accessibility to these sites. We aimed to test the feasibility of fibred confocal fluorescence microscopy (FCFM) to image in situ green fluorescent protein (GFP) in cells of living animals. We used transgenic rabbits expressing the enhanced GFP (eGFP) gene. Detailed tissue architecture and cell morphology were visualised and identified in situ by FCFM. Imaging of vasculature by using FCFM revealed a single blood vessel or vasculature network. We also used non-transgenic female rabbits mated with transgenic males to visualise eGFP expression in extra-foetal membranes and the placenta. Expression of the eGFP gene was confirmed by FCFM. This new imaging technology offers specific characteristics: a way to gain access to organs and tissues in vivo, sensitive detection of fluorescent signals, and cellular observations with rapid acquisition at near real time. It allows an accurate visualisation of tissue anatomical structure and cell morphology. FCFM is a promising technology to study biological processes in the natural physiological environment of living animals.     

In vivo Clonal Tracking of Hematopoietic Stem and Progenitor Cells Marked by Five Fluorescent Proteins using Confocal and Multiphoton Microscopy

We developed and validated a fluorescent marking methodology for clonal tracking of hematopoietic stem and progenitor cells (HSPCs) with high spatial and temporal resolution to study in vivo hematopoiesis using the murine bone marrow transplant experimental model. Genetic combinatorial marking using lentiviral vectors encoding fluorescent proteins (FPs) enabled cell fate mapping through advanced microscopy imaging. Vectors encoding five different FPs: Cerulean, EGFP, Venus, tdTomato, and mCherry were used to concurrently transduce HSPCs, creating a diverse palette of color marked cells. Imaging using confocal/two-photon hybrid microscopy enables simultaneous high resolution assessment of uniquely marked cells and their progeny in conjunction with structural components of the tissues. Volumetric analyses over large areas reveal that spectrally coded HSPC-derived cells can be detected non-invasively in various intact tissues, including the bone marrow (BM), for extensive periods of time following transplantation. Live studies combining video-rate multiphoton and confocal time-lapse imaging in 4D demonstrate the possibility of dynamic cellular and clonal tracking in a quantitative manner.     

Opportunities for biomineralization research using multiscale computed X-ray tomography as exemplified by bone imaging

Biominerals typically have complex hierarchical structures traversing many length scales. This makes their structural characterization complicated, since it requires 3D techniques that can probe full specimens at down to nanometer-resolution, a combination that is difficult – if not impossible – to achieve simultaneously. One challenging example is bone, a mineralized tissue with a highly complex architecture that is replete with a network of cells. X-ray computed tomography techniques enable multiscale structural characterization through the combination of various equipment and emerge as promising tools for characterizing biominerals. Using bone as an example, we discuss how combining different X-ray imaging instruments allow characterizing bone structures from the nano- to the organ-scale. In particular, we compare and contrast human and rodent bone, emphasize the importance of the osteocyte lacuno-canalicular network in bone, and finally illustrate how combining synchrotron X-ray imaging with laboratory instrumentation for computed tomography is especially helpful for multiscale characterization of biominerals.     

Re-evaluation of epoxy resin sections for light and electron microscopic immunostaining.

Epoxy resins provide optimal tissue morphology at both the light and the electron microscopic level and therefore enable correlative studies on semithin and thin sections from the same tissue block. Here we report on an approach to retain these advantages for immunolabeling studies by adapting and combining well-known techniques, i.e., surface etching with sodium ethoxide and heat-mediated antigen retrieval. We propose a simple procedure for immunostaining semithin and thin epoxy resin sections. To check its applicability, well characterized, commercially available antibodies (against E-cadherin, alpha-catenin, and beta-catenin) were used on sections of human small intestine. By light microscopy, the immunostaining efficiency was compared on cryo-, paraffin, and epoxy semithin sections processed in parallel. The most detailed results were obtained on semithin sections, where the labeling precisely delineated the lateral plasma membrane of the enterocytes. At the electron microscopic level the procedure did not damage the structures and allowed an efficient, reproducible immunogold labeling extending homogeneously over exceptionally wide tissue areas. The three antibodies specifically labeled the zonula adherens of the junctional complex between epithelial cells and, in agreement with light microscopic observations, the lateral plasma membrane.